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Data transfer 1

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Data transfer system connects silicon chips with a hair’s-width cable
The advance could improve energy efficiency of data centers and lighten the load for electronics-rich
vehicles.
Daniel Ackerman | MIT News Office
Publication Date:February 24, 2021
Researchers have developed a data transfer system that can transmit information 10 times faster than a
USB. The new link pairs high-frequency silicon chips with a polymer cable as thin a strand of hair. The
system may one day boost energy efficiency in data centers and lighten the loads of electronics-rich
spacecraft.
Presentation of the research.
The research was presented at this month’s IEEE International Solid-State Circuits Conference. The lead
author is Jack Holloway ’03, MNG ’04, who completed his PhD in MIT’s Department of Electrical
Engineering and Computer Science (EECS) last fall and currently works for Raytheon. Co-authors include
Ruonan Han, associate professor and Holloway’s PhD adviser in EECS, and Georgios Dogiamis, a senior
researcher at Intel.
Problem of big data.
The need for snappy data exchange is clear, especially in an era of remote work. “There’s an explosion in
the amount of information being shared between computer chips — cloud computing, the internet, big
data. And a lot of this happens over conventional copper wire,” says Holloway. But copper wires, like
those found in USB or HDMI cables, are power-hungry — especially when dealing with heavy data loads.
“There’s a fundamental tradeoff between the amount of energy burned and the rate of information
exchanged.” Despite a growing demand for fast data transmission (beyond 100 gigabits per second)
through conduits longer than a meter, Holloway says the typical solution has been “increasingly bulky
and costly” copper cables.
Alternative.
One alternative to copper wire is fiber-optic cable, though that has its own problems. Whereas copper
wires use electrical signaling, fiber-optics use photons. That allows fiber-optics to transmit data quickly
and with little energy dissipation. But silicon computer chips generally don’t play well with photons,
making interconnections between fiber-optic cables and computers a challenge. “There’s currently no
way to efficiently generate, amplify, or detect photons in silicon,” says Holloway. “There are all kinds of
expensive and complex integration schemes, but from an economics perspective, it’s not a great
solution.” So, the researchers developed their own.
The team’s new link draws on benefits of both copper and fiber optic conduits, while ditching their
drawbacks. “It’s a great example of a complementary solution,” says Dogiamis. Their conduit is made of
plastic polymer, so it’s lighter and potentially cheaper to manufacture than traditional copper cables.
But when the polymer link is operated with sub-terahertz electromagnetic signals, it’s far more energyefficient than copper in transmitting a high data load. The new link’s efficiency rivals that of fiber-optic,
but has a key advantage: “It’s compatible directly with silicon chips, without any special manufacturing,”
says Holloway.
The team engineered such low-cost chips to pair with the polymer conduit. Typically, silicon chips
struggle to operate at sub-terahertz frequencies. Yet the team’s new chips generate those highfrequency signals with enough power to transmit data directly into the conduit. That clean connection
from the silicon chips to the conduit means the overall system can be manufactured with standard, costeffective methods, the researchers say.
hair’s-width cable
The new link also beats out copper in terms of size. “The cross-sectional area of our cable is 0.4
millimeters by a quarter millimeter,” says Han. “So, it’s super tiny, like a strand of hair.” Despite its slim
size, it can carry a hefty load of data, since it sends signals over three different parallel channels,
separated by frequency. The link’s total bandwidth is 105 gigabits per second, nearly an order of
magnitude faster than a copper-based USB cable. Dogiamis says the cable could “address the bandwidth
challenges as we see this megatrend toward more and more data.”
In future work, Han hopes to make the polymer conduits even faster by bundling them together. “Then
the data rate will be off the charts,” he says. “It could be one terabit per second, still at low cost.”
The researchers suggest “data-dense” applications, like server farms, could be early adopters of the new
links, since they could dramatically cut data centers’ high energy demands. The link could also be a key
solution for the aerospace and automotive industries, which place a premium on small, light devices.
And one day, the link could replace the consumer electronic cables in homes and offices, thanks to the
link’s simplicity and speed. “It’s far less costly than [copper or fiber optic] approaches, with significantly
wider bandwidth and lower loss than conventional copper solutions,” says Holloway. “So, high fives all
round.”
This research was funded, in part, by Intel, Raytheon, the Naval Research Laboratory, and the Office of
Naval Research.
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